Analysis of Genetic Regulatory Mechanisms that Control Ethanolamine Utilization in Enterococcus faecalis

In this project, we studied the genetic regulatory mechanisms that affect utilization of ethanolamine, an abundant compound in the gastrointestinal environment. In Enterococcus faecalis, the ethanolamine utilization (eut) gene cluster encodes for a two-component regulatory system (TCS), comprised of a histidine kinase, EutW, which autophosphorylates upon sensing EA, and a cognate response regulator, EutV, which dimerizes upon receiving the phosphoryl group from EutW and binds the nascent transcript to prevent premature transcription termination. This TCS is responsible for coupling sensing of ethanolamine to production of eut transcripts. However, clues from other organisms had previously suggested that adenosylcobalamin (AdoCbl) might also be an important genetic regulatory signal for the E. faecalis eut genes. Indeed, we discovered a novel trans-acting noncoding RNA (EutX) that contained an AdoCbl-responsive riboswitch. Our data demonstrated that the riboswitch promotes a shortened form of EutX when cellular AdoCbl levels are replete. In contrast, a longer form is synthesized when AdoCbl levels are depleted. We demonstrated that structural motifs contained in the longer form of EutX act to sequester the EutV protein, preventing it from promoting transcription elongation of eut transcripts. These unexpected data revealed an important new type of regulatory mechanism for riboswitch RNAs. In support of this overall genetic regulatory model, we recapitulated the full genetic circuitry in a heterologous host. Using this system, we employed extensive site-directed mutagenesis to examine the functional importance of highly conserved EutV residues. This led to the identification of a cluster of positively charged residues, which we speculated are important determinants for RNA-binding activity. Consistent with this hypothesis, mutations of these residues resulted in loss of RNA-binding activity. Furthermore, we also explored whether the eut gene cluster was affected by additional genetic regulatory mechanisms. From these efforts, we concluded that oxygen is not a genetic regulatory feature of eut genes, in contrast to previously published speculation. However, we did find that it is likely to be repressed under conditions of high glucose. Therefore, these aggregate studies revealed new mechanisms of post-initiation genetic regulation, and showed how E. faecalis specifically controls expression of ethanolamine catabolism genes

Dynamical reconstruction of the global ocean state during the Last Glacial Maximum

The global ocean state for the modern age and for the Last Glacial Maximum (LGM) was dynamically reconstructed with a sophisticated data assimilation technique. A substantial amount of data including global seawater temperature, salinity (only for the modern estimate), and the isotopic composition of oxygen and carbon (only in the Atlantic for the LGM) were integrated into an ocean general circulation model with the help of the adjoint method, thereby the model was optimized to reconstruct plausible continuous fields of tracers, overturning circulation and water mass distribution. The adjoint‐based LGM state estimation of this study represents the state of the art in terms of the length of forward model runs, the number of observations assimilated, and the model domain. Compared to the modern state, the reconstructed continuous sea‐surface temperature field for the LGM shows a global‐mean cooling of 2.2 K, and the reconstructed LGM ocean has a more vigorous Atlantic meridional overturning circulation, shallower North Atlantic Deep Water (NADW) equivalent, stronger stratification, and more saline deep water

Mechanistic Analysis of CCP1 in Generating ΔC2 α-Tubulin in Mammalian Cells and Photoreceptor Neurons

An important post-translational modification (PTM) of α-tubulin is the removal of amino acids from its C-terminus. Removal of the C-terminal tyrosine residue yields detyrosinated α-tubulin, and subsequent removal of the penultimate glutamate residue produces ΔC2-α-tubulin. These PTMs alter the ability of the α-tubulin C-terminal tail to interact with effector proteins and are thereby thought to change microtubule dynamics, stability, and organization. The peptidase(s) that produces ΔC2-α-tubulin in a physiological context remains unclear. Here, we take advantage of the observation that ΔC2-α-tubulin accumulates to high levels in cells lacking tubulin tyrosine ligase (TTL) to screen for cytosolic carboxypeptidases (CCPs) that generate ΔC2-α-tubulin. We identify CCP1 as the sole peptidase that produces ΔC2-α-tubulin in TTLΔ HeLa cells. Interestingly, we find that the levels of ΔC2-α-tubulin are only modestly reduced in photoreceptors of ccp1−/− mice, indicating that other peptidases act synergistically with CCP1 to produce ΔC2-α-tubulin in post-mitotic cells. Moreover, the production of ΔC2-α-tubulin appears to be under tight spatial control in the photoreceptor cilium: ΔC2-α-tubulin persists in the connecting cilium of ccp1−/− but is depleted in the distal portion of the photoreceptor. This work establishes the groundwork to pinpoint the function of ΔC2-α-tubulin in proliferating and post-mitotic mammalian cells